| NSF Org: |
CMMI Division of Civil, Mechanical, and Manufacturing Innovation |
| Recipient: |
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| Initial Amendment Date: | May 1, 2017 |
| Latest Amendment Date: | May 1, 2017 |
| Award Number: | 1663654 |
| Award Instrument: | Standard Grant |
| Program Manager: |
Joy Pauschke
jpauschk@nsf.gov (703)292-7024 CMMI Division of Civil, Mechanical, and Manufacturing Innovation ENG Directorate for Engineering |
| Start Date: | July 1, 2017 |
| End Date: | June 30, 2021 (Estimated) |
| Total Intended Award Amount: | $634,391.00 |
| Total Awarded Amount to Date: | $634,391.00 |
| Funds Obligated to Date: |
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| History of Investigator: |
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| Recipient Sponsored Research Office: |
1500 SW JEFFERSON AVE CORVALLIS OR US 97331-8655 (541)737-4933 |
| Sponsor Congressional District: |
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| Primary Place of Performance: |
OR US 97331-8507 |
| Primary Place of
Performance Congressional District: |
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| Unique Entity Identifier (UEI): |
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| Parent UEI: |
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| NSF Program(s): | Engineering for Natural Hazard |
| Primary Program Source: |
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| Program Reference Code(s): |
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| Program Element Code(s): |
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| Award Agency Code: | 4900 |
| Fund Agency Code: | 4900 |
| Assistance Listing Number(s): | 47.041 |
ABSTRACT
The consequences of earthquake-induced liquefaction are not trivial; for example, $15B of damage was attributed to soil liquefaction resulting from the recent Canterbury Earthquake Sequence in New Zealand. Large portions of the United States, from Alaska to California and eastward to the New Madrid Seismic Zone and coastal South Carolina and north to the St. Lawrence Seaway, are prone to the impacts from earthquakes. Earthquakes such as those in New Zealand and others have raised awareness about limitations in our understanding of the cyclic response of natural soil deposits. These limitations have arisen through continued use of the traditional practice of simplifying geotechnical analyses by considering two main soil types: drained sands and undrained clays. Design methodologies for nearly all geotechnical systems have developed along these two distinct lines. However, many natural soil deposits do not fit into these simple categories; transitional silty soils, the subject of this research, are an example. This study aims to answer pertinent questions concerning the cyclic response of transitional silty soils through systematic and coordinated field and laboratory studies that will improve our understanding of the potential for large deformations and loss of life and property during large earthquakes. The findings of this research will have broad application across the nation and globe. Furthermore, this research will have a parallel objective of inspiring the next generation of STEM leaders. Collaboration with the Hatfield Marine Science Center (HMSC) in Newport, Oregon will allow our outreach efforts to reach 150,000 visitors and 40,000 K-12 students and teachers per year, through: (1) public demonstrations of liquefaction and in-situ cyclic tests with a large mobile shaker truck, (2) a compilation of video demonstrations, data, and interviews with the researchers into a permanent interactive exhibit, and (3) development of instructional modules for HMSC staff to help their established outreach effort expand instruction to include coastal hazards such as the Cascadia Subduction Zone and associated tsunami. The demonstrations will be leveraged to form permanent exhibits and instructional modules, which will greatly extend this outreach effort.
This research will improve our understanding of the in-situ and laboratory cyclic response of silt soils including nonlinearity, degradation of stiffness, triggering of destabilizing excess pore pressures, and the corresponding post-shaking consequences. Specifically, this study will: (1) narrow the threshold fines content and plasticity separating "sand-like" and "clay-like" responses to cyclic shear stresses/strains and identify critical threshold states; (2) compare the in-situ, uniaxial and biaxial cyclic response of transitional soils to understand how changes in strong ground motion directionality impacts generation of pore pressure and volumetric strain; (3) determine the effect of soil fabric, stress history, and degree of saturation on the cyclic and post-cyclic response of transitional soils; (4) link the regional findings from this work to previous efforts on transitional soils; and (5) inspire future seismologists, geologists, earthquake engineers, and natural hazard and resilience planners through a long-lived, coordinated outreach program. This work concentrates on experiments that target small-to-large shear strains, using techniques that range from in-situ cyclic loading from large mobile shakers and blast liquefaction, to specialized and coordinated laboratory tests, allowing the development of an unprecedented dataset critical for improving the understanding of the in-situ and elemental level cyclic response to be bridged.
PUBLICATIONS PRODUCED AS A RESULT OF THIS RESEARCH
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PROJECT OUTCOMES REPORT
Disclaimer
This Project Outcomes Report for the General Public is displayed verbatim as submitted by the Principal Investigator (PI) for this award. Any opinions, findings, and conclusions or recommendations expressed in this Report are those of the PI and do not necessarily reflect the views of the National Science Foundation; NSF has not approved or endorsed its content.
Large portions of the United States, from Alaska to California and eastward to the New Madrid Seismic Zone and coastal South Carolina and north to the St. Lawrence Seaway, are prone to the impacts from earthquakes, such as soil liquefaction. The consequences of earthquake-induced liquefaction are substantial as demonstrated in the lessons learned from the recent Canterbury Earthquake Sequence in New Zealand, which included the identification of limitations of our knowledge concerning the seismic behavior of transitional soils. These limitations have arisen through continued use of the traditional practice of simplifying geotechnical analyses by considering two main soil types: drained sands and undrained clays. Design methodologies for nearly all geotechnical systems have developed along these two distinct lines. However, many natural soil deposits do not fit into these simple categories, such as transitional silty soils.
This study focused on linking the in-situ field behavior of transitional, low plasticity silt soils to that observed in common laboratory tests to identify similarities and differences between these scenarios and improve our understanding of the seismic behavior of these soils during earthquakes. Accordingly, three main activities were conducted to perform this research: (1) characterizing the subsurface characteristics of two field sites selected for in-situ seismic loading, (2) developing and executing a new field testing technique implementing controlled blasting, and validating the technique using an independent field loading source, and (3) performing a detailed suite of laboratory tests to evaluate similarities and differences between the field and laboratory behavior.
An instrumented deposit of silt soil was subject to staged loading, field shaking tests and the controlled blasting technique to observe the in-situ dynamic response. The variation of excess pore pressure and nonlinear shear modulus with shear strain was observed using both testing techniques and indicated the same response over the range in shear strain shared among the two techniques, validating the novel controlled blasting test method. The controlled blasting technique extended the range in dynamic shear strain possible in-situ by one order of magnitude relative to the mobile shaking test. Laboratory tests conducted to simulate the staged loading field tests and controlled blasting tests revealed that certain behaviors can, and cannot, be replicated in the laboratory as a function of differing boundary conditions and drainage states.
The novel technique developed and validated in this study can be applied to any kind of soil and at any depth, providing new avenues for in-situ dynamic testing to support improved understanding of the dynamic properties of any geomaterial. Results from this study will serve to narrow the threshold soil indices separating "sand-like" and "clay-like" responses to cyclic shear stresses and shear strains and identify critical threshold states that improve our understanding of the potential for large deformations and loss of life and property during large earthquakes. This knowledge is critical in building resilient infrastructure with broad global application.
Last Modified: 10/28/2021
Modified by: Armin W Stuedlein
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